Growth of grana from "primary" thylakoids in Phaseolus vulgaris

The plastids of young dark-grown bean leaves, exposed to periodiclight are agranal, devoid of chlorophyll b and contain primarythylakoids and chlorophyll a. Transfer of these plants to continuousillumination results in synthesis of new chlorophyll a, chlorophyllb and grana. This study was done in order to study whether andhow the grana are formed from preexisting primary thylakoids.¹⁴C--aminolevulinic acid was used to label the chlorophyll aof the primary thylakoids, and its fate was studied after transferof the plants to continuous light. It was found that chlorophyll b and grana become ¹⁴C-labelled.The total radioactivity of chlorophyll b per bean increasedwith the parallel decrease of that of chlorophyll a. All subchloroplastfractions, obtained after digitonin disruption of chloroplasts,contained chlorophyll a of equal specific radioactivity. Thespecific radioactivity of chlorophyll b was lower than thatof chlorophyll a, and, in addition, it was lower in the granathan in the stroma lamellae fraction. The data suggest that chlorophyll b is formed from chlorophylla; the grana are formed by stacking of preexisting primary thylakoids;chlorophyll b is synthesized faster in the grana than the stromalamellae; the newly formed chlorophyll a molecules are distributedat random throughout the developing photosynthetic membraneand not on specific growing sites. (Received April 24, 1976; )     

A Biochemical Study of Spore Germination in the Blue-green Alga Anabaena doliolum

The spores of Anabaena doliolum formed in light (light spores)and after transfer to darkness (dark spores) are biochemicallydifferent in that the light spores contain chlorophyll a andphycocyanin, while dark spores seem to lack them. The apparentbiosyntheses accompanying dark-spore germination seem to proceedin the following order: RNA, chlorophyll a, phycocyanin andDNA. Results of chloramphenicol treatment indicate that proteinsynthesis precedes RNA synthesis. The biosynthetic events followingRNA synthesis show a requirement for light.     

The presence of chlorophyll b and the estimation of phaeopigments in marine phytoplankton

A reverse-phase h.p.l.c. technique was used to estimate theconcentration of chlorophyll b in phytoplankton cultures, fecalpellets of Calanus pacificus, and suspended paniculate matterfrom the Central North Pacific, Oregon coastal waters, and DabobBay (a temperate fjord in Puget Sound, WA, USA). The purposewas to assess the distribution of this pigment in the euphoticzone and its effect on the fluorometnc estimation of phaeopigments.Analyses of natural waters confirm high chlorophyll b concentrations(median mass ratio of b:a > 0.3) at the depth of the chlorophylla maximum in tropical waters while values for temperate planktonare relatively low (median mass ratio of chl b:a = 0.05) andpatchy. Zooplankton fecal pellets showed a significant enrichmentin chlorophyll b, suggesting grazing as a mechanism to explainhigh concentrations of this pigment at the bottom of the euphoticzone. It is estimated that the presence of chlorophyll b couldcause an average overestimation of phaeopigment concentrationby the fluorometnc technique of 38% between 0 and 200 m in theCentral North Pacific. This effect is more pronounced at thelayer of chlorophyll b maximum (120–140 m). ¹Present address: Marine Biology Research Division, A-002, ScrippsInstitution of Oceanography, La Jolla, CA 92093, USA     

Changes in the Levels of Chlorophyll and Light-Harvesting Chlorophyll a/b Protein of PS II in Rice Leaves Aged under Different Irradiances from Full Expansion through Senescence

Effects of irradiance on changes in the amounts of chlorophyll(Chl) and light-harvesting chlorophyll a/b protein of PS II(LHCII) were examined in senescing leaves of rice (Oryza sativaL.). Results of treatments at two irradiances (100% and 20%natural sunlight) were examined after the full expansion ofthe 13th leaf throughout the course of senescence. With 20%sunlight, the Chl content decreased only a little during leafsenescence, while with 100% sunlight it decreased appreciably.Similarly, the amount of LHCII protein during treatment with20% sunlight remained almost constant. However, the ratio ofChl a/b during the shade treatment decreased significantly andthe rate of decrease was greater than during the full-sunlighttreatment. The ratio of Chl a/b for Chl a and b bound to LHCIIwas about 1.2, irrespective of leaf age or irradiance treatment.When the amounts of Chl bound to LHCII were calculated fromthe total leaf content of Chl and the ratio of Chl a/b, assuminga ratio of Chl a/b bound to LHCII of 1.2, they were well correlatedwith the amounts of LHCII protein. Changes in the amounts of LHCII synthesized during the two irradiancetreatments were examined using an ¹⁵ tracer. Incorporation of¹⁵N into LHCII declined dramatically during both treatmentsfrom full expansion through senescence, suggesting that therewas little synthesis of LHCII protein during that time. In addition,the amount of LHCII synthesized during senescence was lowerduring the shade treatment than during the 100% sunlight treatment.These results indicate that the absence of an apparent changein levels of LHCII with shade treatment during senescence wascaused by the very low rate of turnover of LHCII protein. (Received June 17, 1992; Accepted September 28, 1992)     

Formation of Chlorophyll-Protein Complexes during Greening 1. Distribution of Newly Synthesized Chlorophyll among Apoproteins

The relationship between the accumulation of Chl and the apoproteinsof the light-harvesting Chl a/b-protein complex of PS II (LHCII)during the greening of cucumber cotyledons was studied. LHCIIapoproteins were not detected in etiolated cotyledons. Uponillumination, Chl a was formed as a result of photoconversionof protochlorophyllide (Pchlide) which had accumulated in thedark. During the lag period that preceded the accumulation ofChl, a small amount of LHCII apoproteins appeared. The amountof LHCII apoproteins increased with increases in levels of Chlb, though somewhat more rapidly during the first 10 h of greening.Treatment with benzyladenine (BA) or levulinic acid (LA) wasused to vary the supply of Chl a for apoproteins by promotingor inhibiting the synthesis of Chl a, respectively. LA decreasedbut BA increased the rate of accumulation of Chl b and LHCIIapoproteins. Only small amounts of Chl b and LHCII apoproteinswere formed under intermittent illumination. However, in thepresence of chloramphenicol (CAP), which inhibits the synthesisof plastome-coded proteins including apoproteins of the P700-Chla-protein complex (CP1) and a Chl a-protein complex of PS II(CPa), we observed the accumulation of Chl b and LHCII apoproteins,both of which are of nuclear origin. During incubation in thedark after intermittent exposure to light, CAP alone allowedneither destruction nor accumulation of Chl b and LHCII apoproteins,but it did enhance the effect of CaCl₂ in inducing both Chlb and these apoproteins. These results can be explained by assumingthat apoproteins of CP1 and CPa have a higher affinity for Chla than do LHCII apoproteins. When the availability of Chl ais limited, these apoproteins compete with one another for Chla, with the resultant preferential formation of CP1 and CPa.However, when the supply of Chl a becomes large enough for saturationof apoproteins of CP1 and CPa, some of the Chl a is incorporatedinto LHCII apoproteins either directly or after conversion toChl b. Thus, the formation of different Chl-protein complexes(CPs) is regulated by the relative rates of synthesis of Chla and apoproteins and by differential affinities of the apoproteinsfor Chl a. ⁴Present address: Kyowa Hakko Co., Ltd., 4041, Ami-machi, Inashiki,Ibaraki, 300-03 Japan (Received September 14, 1989; Accepted April 26, 1990)     

Changes in Average Cell Concentrations of Various Constituents During Synchronous Division of Platymonas striata Butcher (Prasinophyceae)

The changes in the average cell composition of the green algaPlatymonas striata Butcher have been determined during a singlecell cycle in synchronous culture induced by an alternatinglight/dark regime. The cells divided into two at the onset ofdarkness, but remained attached until exposed to light 10 hlater. There appeared to be virtually no net synthesis of constituentsduring the dark period. On exposure to light most components(apart from DNA) showed some continuing net synthesis, but inthe majority of cases there was a short part of this light syntheticperiod in which there was very active net synthesis. The activesynthetic period was frequently immediately prior to the onsetof division. DNA synthesis occurred only in the 6 h precedingdivision. The major period of net protein synthesis occurredwhilst the divided cells were separating, at the commencementof the light period. The other factors studied were RNA, carbohydrate,chlorophyll a, chlorophyll b, carotenoids, phospholipids, acid-solublecompounds, and phosphorus uptake. The results are discussed.     

Changes in Chlorophyll a and b Content in Dark-Incubated Cotyledons Excised from Illuminated Seedlings: THE EFFECT OF CALCIUM

Cucumber seedlings were illuminated for various time periods, cotyledons excised, placed in the dark, and changes in chlorophyll a and b content monitored. During the dark periods, chlorophyll b content decreased while chlorophyll a did not. When the illumination time was lengthened, the percentage of chlorophyll b decomposition from initial levels decreased. Ca²⁺ at 50 millimolar prevented the decrease in chlorophyll b and caused a decrease in chlorophyll a. The effect of Ca²⁺ decreased with increased illumination time. Cycloheximide and chloramphenicol inhibited chlorophyll b decrease, but did not induce chlorophyll a decrease.     

Formation of Chlorophyll-Protein Complexes in Greening Cucumber Cotyledons in Light and then in Darkness

The changes in chlorophyll-protein complexes (CPs) in cucumbercotyledons during illumination and subsequent dark incubationwere studied by SDS-polyacrylamide gel electrophoresis. Whenetiolated cucumber seedlings were illuminated, chlorophyll wassynthesized and CPs were formed. In the early phase of greening(6 h of illumination), light-harvesting chlorophyll a/b-proteincomplex (LHCP) was the main GP. As the greening proceeded, P700chlorophyll a-protein complex (CP1) accumulated. When 6-h illuminatedseedlings were transferred to darkness, CP1 accumulated concomitantlywith a decrease in LHCP without new chlorophyll synthesis. Thechanges in the amounts of CPs in the dark became smaller withthe progress of greening and were not observed after 72 h ofillumination. These changes were confirmed by examining thechlorophyll/P700 ratio and the low temperature absorption spectrumof cotyledons. These results suggest that in the early phaseof greening, CPs were unstable and their chlorophyll moleculeseasily exchanged with those of other kinds of CPs. (Received October 14, 1982; Accepted December 1, 1982)     

Studies on chlorophyllase of Chlorella protothecoides II. Formation of atypical chlorophyllide a

When chlorophyll a was incubated with a preparation of chlorophyllaseextracted with Triton X-100 from methanol-acetone powder ofChlorella protothecoides, the substrate was changed to chlorophyllidea, and subsequently to an atypical form of chlorophyllide a.The formation of an atypical form of chlorophyllide was notdetected in the reaction with chlorophyll b as substrate, norin the reaction with another preparation of chlorophyllase extractedfrom the algal cells. (Received August 18, 1969; )     

Chromatographic separation of photosystems I and II from the thylakoid membrane isolated from a thermophilic blue-green alga

The thylakoid membrane of a thermophilic blue-green alga, Synechococcussp., was separated into four chlorophyll-containing fractionsby a single chromatographic manipulation with a diethylaminoethyl-cellulosecolumn after digitonin treatment. Photosystems I and II, orchlorophyll a forms, were unevenly distributed among the fourfractions, which were designated F-1, F-2, F-3 and F-4 in theorder of elution from the column. F-1 has a simple composition of the chlorophyll a form and totallylacks photochemical activity. This fraction may be an antennachlorophyll a-protein in the blue-green alga. F-2 is rich inshorter wavelength chlorophyll a forms and shows the three-bandedfluorescence emission spectrum characteristic of photosystemII at liquid nitrogen temperature. This fraction is highly activein 2,6-dichloroindophenol photoreduction and contains one photooxidizablecytochrome b₅₅₉ per 50–100 chlorophyll a, whereas theP-700 content is as low as one P-700 per 2,000 chlorophyll a.Thus, F-2 represents photosystem II in a highly purified state.F-3 is rich in photosystem I, since this fraction is inactivein 2,6-dichloroindophenol photoreduction, and contains one P-700per 200 chlorophyll a and smaller amounts of cytochrome b₅₅₉.Longer wavelength chlorophyll a forms are abundant and a peakat 730 nm is the most prominent in the low-temperature fluorescencespectrum in this fraction. F-4, which consists of larger membranefragments shows spectral and photochemical features similarto those of F-3. (Received August 8, 1979; )     

Inhibition of growth and photosynthesis of freshwater phytoplankton by ultraviolet A (UVA) radiation and subsequent recovery from stress

The effect of ultraviolet A (UVA) on growth and photosyntheticrate was studied in diatoms (Melosira spp.) of the phytoplanktonof a eutrophic lake and a cultured green alga Chloretla ellipsoidea.The cells were incubated under photosynthetically active radiation(PAR) (–UVA) or PAR + UVA conditions (+UVA). Growth ofC.ellipsoidea was retarded under +UVA, as shown by an increasein the lag period, but the rate of exponential growth was almostthe same in + and –UVA conditions. The photosyntheticrate was depressed markedly by UVA in Chlorella cells grownunder –UVA. In contrast, cells grown in +UVA showed onlyslight inhibition by UVA and after exposure to UVA for 6 daysthere was no inhibition. During the growth experiment, the cellularchlorophyll a content was higher in +UVA than +UVA grown cells.A similar effect was observed in diatoms from the eutrophicLake Suwa. In vivo fluorescence with (F_a) and without 3-(3,4-dichloropheny)-l,l-dimethylurea (DCMU) (F_b) and the photosynthetic rate were measured forC.ellipsoidea and the diatoms for 5 h under + and –UVAconditions. Soon after C.ellipsoidea had been subjected to +UVA,F_b and F_a / F_b decreased quickly and reached minima after 40min and 1 h, respectively. The suppressed in vivo fluorescenceresumed and full recovery was achieved after 4 h. This suggeststhat reactivation of the photosystem is acquired under prolongedexposure to UVA. A similar shift of F_a + F_b, but no change inFb, was found in diatoms by exposure to UVA. Changes in photosyntheticoxygen evolution by C.ellipsoidea under +UVA were similar tochanges in F_a + F_b. Degradation of chlorophyll a extracted inmethanol was enhanced by UVA. The rate of degradation by UVAwas independent of temperature from 15 to 34°C, suggestinga photochemical reaction. The results indicate that C.ellipsoideaand Melosira spp. acclimatize to prolonged UVA exposure by reactivationof the photosystem and enhanced cellular chlorophyll a synthesis.The ecological importance of these results to phytoplanktonproductivity in natural aquatic environments is discussed.     

The Influence of Stress Conditions on Chlorophyll Content of Two Range Grasses with Contrasting Photosynthetic Pathways

The influence of various treatments and temperature regimeson total chlorophylls and on the chlorophyll a:b ratio of westernwheatgrass and blue grama plants was investigated at differenttime intervals during the 120-day growth period. Western wheatgrass,a C₃ species, accumulated greater amounts of chlorophyll thandid blue grama plants, a C₄ species. Maximum concentrations(mg gd wt^–1) of chlorophylls in western wheatgrass andin blue grama were recorded at the lower (13/7°C) and higher(30/18°C) temperature regimes. Nitrogen fertilizer alonedecreased the chlorophyll content in both species. The chlorophylla:b ratio in blue grama ranged from an average of 2·00under irrigated plus fertilized conditions to 3·00 undercontrol and fertilized conditions. On the other hand, the chlorophylla:b ratio in western wheatgrass remained constant at 3·00throughout the growing season under various treatments and temperatureregimes.     

Effect of Sodium Dodecyl Sulfate on Structure and Spectroscopic Characteristics of Water-Soluble Chlorophyll Protein Complex Isolated from Stems of Lepidium virginicum

The relationship between structure and spectroscopic characteristicsof the watersoluble chlorophyll protein complex isolated fromstems of Lepidium virginicum (CP663S) was studied. Additionof 0.08% SDS induced a red shift of the 663 nm absorption maximum.At the same time, under excitation at 435 nm, the maximum offluorescence emission shifted from 672 nm to 675 nm and thefluorescence yield increased. When CP663S was excited at 480nm, the 660 nm emission band of chlorophyll b became more prominent.Fluorescence lifetime of emission from chlorophyll a increasedon addition of SDS. The energy transfer from chlorophyll b tochlorophyll a was decreased by the SDS addition, as judged bythe fluorescence spectra and lifetime measurement. Symmetricalpositive and negative peaks of the circular dichroism (CD) spectrumaround 669 nm, which indicate the interaction between chlorophylla molecules at short distances, disappeared after addition ofSDS. These SDS-induced changes of spectroscopic characteristicsoccurred in similar SDS concentration ranges and were reversible.SDS polyacrylamide gel electrophoresis cleaved CP663S into subunits.Chlorophyll molecules moved with protein moieties. Glutaraldehydetreatment suppressed the effects of SDS on absorption, fluorescenceand CD characteristics. We conclude that chlorophyll moleculesin CP663S are in the hydrophobic region of the protein and theinteraction between chlorophyll a molecules occurs at shortdistances. Changes of spectroscopic characteristics are a resultof cleavage of CP663S. ¹Present address: National Institute for Basic Biology, Okazaki444, Japan. (Received November 22, 1982; Accepted May 31, 1983)     

Purification and Characterization of a Light-Harvesting Chlorophyll-Protein Complex from the Marine Eustigmatophyte Nannochloropsis sp.

Light-harvesting chlorophyll-protein was purified from thylakoidmembranes of the marine unicellular alga Nannochloropsis sp.(Eustigmatophyceae), which contains neither chlorophyll b norchlorophyll c. Solubilization of thylakoid membranes with octyl-ß-D-glucopyranosideor with digitonin followed by separation on sucrose densitygradient yielded a chlorophyll-protein complex composed of anapoprotein of 26 kDa and an average of 9 chlorophyll a and 4violaxanthin molecules per apoprotein. Excitation spectra ofchlorophyll a fluorescence for the algal thylakoid membranesindicated energy transfer from the xanthophylls; however, anyattempt to solubilize the membranes greatly decreased energytransfer which was further reduced as the purification proceeded.The 26 kDa polypeptide of the isolated light-harvesting complexdid not cross-react with polyclonal antibodies raised againstanalogous proteins from higher plants and chlorophyll a/c alga.The N-terminus amino acid sequence of the apoprotein shows significantstructural similarity to the N-termini of the mature light harvestingfucoxanthin, chlorophyll a/c proteins from the diatom Phaeodactylumtricornutum, but not with the N-termini of light-harvestingproteins from chlorophyll a/b containing organisms. (Received June 25, 1992; Accepted July 28, 1992)     

Relationship between Photosynthesis and Chlorophyll Content during Leaf Senescence of Rice Seedlings

Photosynthetic oxygen evolution, chlorophyll contents and chlorophylla /b ratios of 3rd to 6th leaves of rice seedlings were measuredto examine whether or not inactivation of photosynthesis duringsenescence is related to loss of chlorophyll. Photosyntheticactivity decreased more rapidly than chlorophyll content duringleaf senescence; as a result, the lower the leaf position, thelower was the rate of oxygen evolution determined on the basisof chlorophyll. Chlorophyll ab ratio also decreased with advancingsenescence. Electrophoretic analysis revealed that the declinein chlorophyll ab ratio is due to more rapid degradation ofthe reaction center complexes than light-harvesting chlorophyllab proteins of photosystem II and that the photosystem I reactioncenter disappears in parallel with the inactivation of photosynthesis.A simple method was developed to estimate the amounts of chlorophylla associated with the reaction center complexes of the two photosystemsfrom the total chlorophyll contents and chlorophyll ab ratiosof leaves. Rates of oxygen evolution, determined on the basisof chlorophyll a bound to the reaction center complexes, remainedconstant throughout the course of senescence. Thus, inactivationof photosynthesis is closely related with loss of the reactioncenter complexes during leaf senescence of rice seedlings. Theresults suggest that loss of photosynthesis is mainly causedby loss of a functional unit of photosynthesis or by a decreasein the number of whole chloroplasts. (Received April 22, 1987; Accepted August 13, 1987)     

Pigment Composition of a Novel Oxygenic Photosynthetic Prokaryote Containing Chlorophyll d as the Major Chlorophyll

The principal pigment found in the majority of oxygenic photosyntheticorganisms is known to be chlorophyll a. However, we isolateda new oxygenic photosynthetic prokaryote that contained chlorophylld as a predominant pigment with chlorophyll a being a minorpigment. Chlorophyll d had previously been noted but its naturaloccurrence and function remained unclear. Cells of the new prokaryotehad an absorption maximum at red region of 714–718 nmdue to chlorophyll d absorption, but no characteristic absorptionpeak of chlorophyll a around 680 nm was observed. Chlorophylld of the new organism was identified spectrophotometricallyin several solvents and its chemical structure was confirmedby NMR and FABMS analysis. The cell also contained a chlorophyllc-like pigment, zeaxanthin and a-carotene but not chlorophyllb and ß-carotene. The content of chlorophyll d accountedfor more than 2% of the cell dry weight, while the content ofchlorophyll a was less than 0.1%. The chlorophyll a/d ratioremained between 0.03 and 0.09 under different culture conditions.The light absorption characteristics and the high content ofchlorophyll d along with the small content of chlorophyll aindicated the existence of a new light utilization mechanisminvolving chlorophyll d. (Received October 7, 1996; Accepted December 16, 1996)     

Conversion of chlorophyll b to chlorophyll a precedes magnesium dechelation for protection against necrosis in Arabidopsis

Chlorophyll is a deleterious molecule that generates reactive oxygen species and must be converted to non‐toxic molecules during plant senescence. The degradation pathway of chlorophyll a has been determined; however, that of chlorophyll b is poorly understood, and multiple pathways of chlorophyll b degradation have been proposed. In this study, we found that chlorophyll b is degraded by a single pathway, and elucidated the importance of this pathway in avoiding cell death. In order to determine the chlorophyll degradation pathway, we first examined the substrate specificity of 7‐hydroxymethyl chlorophyll a reductase. 7‐hydroxymethyl chlorophyll a reductase reduces 7‐hydroxymethyl chlorophyll a but not 7‐hydroxymethyl pheophytin a or 7‐hydroxymethyl pheophorbide a. These results indicate that the first step of chlorophyll b degradation is its conversion to 7‐hydroxymethyl chlorophyll a by chlorophyll b reductase, although chlorophyll b reductase has broad substrate specificity. In vitro experiments showed that chlorophyll b reductase converted all of the chlorophyll b in the light‐harvesting chlorophyll a/b protein complex to 7‐hydroxymethyl chlorophyll a, but did not completely convert chlorophyll b in the core antenna complexes. When plants whose core antennae contained chlorophyll b were incubated in the dark, chlorophyll b was not properly degraded, and the accumulation of 7‐hydroxymethyl pheophorbide a and pheophorbide b resulted in cell death. This result indicates that chlorophyll b is not properly degraded when it exists in core antenna complexes. Based on these results, we discuss the importance of the proper degradation of chlorophyll b.     

Presence of the Photoactive Reaction-Center Chlorophyll of PSI (P700) in Dark-Grown Cells of a Chlorophyll-Deficient Mutant of Chlorella kessleri

Compositions of pigments and polypeptides of pale green membranesthat had been isolated from dark-grown cells of a chlorophyll-deficientmutant of Chlorella kessleri were investigated. They containedChl a in a level corresponding to about 1% of that present inthe thylakoid membranes isolated from autotrophically grownwild-type cells and a trace amount of chlorophyllide a, butneither Chl b nor carotenoids. The polypeptide profile of themutant membranes was similar to that of membranes isolated fromwild-type cells that were grown in the dark. Neither the chlorophyll-bindingsubunits of PSI nor the apoproteins of LHCP were detected bySDS-PAGE and immunoblot analysis. However, the light-minus-darkdifference spectrum of the mutant membranes revealed the presenceof the reaction-center chlorophyll of PSI (P700) at a molarratio of 190 chlorophyll (Chl a plus Chlide a) per P700. P700was more stable than Chl a and Chlide a in the light so thatprolonged illumination led to a decline in the Chl/P700 ratioto 24. The initial rate of P700 photooxidation in the mutantmembranes was comparable to that in CP1 isolated from the dark-grownwild-type cells. Under illumination with strong light, the initialrate was decreased in parallel to the decrease in Chl/P700 ratio.The results suggest that most of Chi present in the mutant membranescan transfer excitation energy to P700. (Received March 13, 1998; Accepted August 7, 1998)     

Properties of light-harvesting chlorophyll a/b-protein, and photosystem I chlorophyll a-protein, purified from digitonin extracts of spinach chloroplasts by isoelectrofocusing

A procedure for purifying both light-harvesting chlorophylla/b-protein and photosystem I chlorophyll -protein from digitoninextracts of spinach chloroplasts is described. This procedureuses isoelectrofocusing on Ampholine at the last step and permitsisolating all of the chlorophyll-proteins from the same extractin a better yield and a highly pure state. The purified light-harvesting chlorophyll a/b-protein whichhas an isoelectric point (pi) of 4.35 (?0.1) and a single polypeptideof 24 kilodaltons (kD), shows slightly higher chlorophyll a/Aratio of 1.35 than the values reported for the preparationsobtained by anionic detergents. This chlorophyll-protein exhibitsa markedly high and sharp fluorescence band at 681 nm at 77?Kwhich is not found on the chloroplast emission spectrum. Photosystem I chlorophyll a-protein focuses on Ampholine intotwo bands with pi values of 4.75 (?0.1) and 4.80 (?0.1). Thesetwo fractions show the same absorption spectra (maximum at 678nm at room temperature) and emission spectra (maximum at 734nm at 77?K) and have the same constituent polypeptides: onelarge band at 55–64 kD and six minor bands (21.5, 20,19, 18, 16 and 15 kD). The polypeptide composition and the P-700to chlorophyll a ratio (1 to ca. 80) of this preparation arevery similar to those of the photosystem I reaction center preparationobtained from Swiss chard chloroplasts by Bengis and Nelson(8). (Received October 31, 1978; )     

Determination of chlorophylls and carotenoids of marine phytoplankton: separation of chlorophyll a from divinylchlorophyll a and zeaxanthin from lutein

A rapid reverse-phase HPLC method is presented for the identificationand quantification of most of the phytoplankton pigments. Thismethod yields the resolution of divinyl-chlorophyll a and chlorophylla, as well as the partial resolution of lutein and zeaxanthin,and of divinyl-chlorophyll b and chlorophyll b. In addition,chlorophylls c_1,2 and c₃ are well resolved. The analysis timefor one sample is 20 mm, which makes this method particularlysuited when large numbers of samples have to be processed.